JP2005520370A - IP multicast services over broadcast channels - Google Patents

Abstract

A method of and apparatus for providing an Internet Protocol multicast service wherein multicast data is transmitted through multicast routers (8) to user stations (9) over a digital broadcast channel (especially DVB-T) together with digital broadcast signals, at least if a request has been received from a user station (9) for the multicast data,. The transmission of the multicast data by a multicast router is conditional upon the reception of a request for said multicast data from that multicast router by a plurality of the user stations (9). The number of requests from the user stations (9) has to be greater than a threshold number, which is a function of the available bandwidth for multicast transmission over the broadcast channel. Information concerning the requests for the multicast data by the user stations (9) is unavailable to the other user stations (9). <IMAGE>

Description

[Field of the Invention]
The present invention relates to the transmission of Internet Protocol (“IP”) multicast services over broadcast channels.

[Background of the invention]
The most common type of IP communication is unicast communication, in other words, communication is established between the nodes identified in the datagram in which the individual addresses of the nodes are transmitted. If the server is to send the same datagram to more than one address, it must repeat the datagram with each of the individual addresses. Thus, the unicast method of transmission would be suitable for mass distribution of messages or other communications to many destinations.

  A modified protocol can be used for multicast services to meet the requirement to send Internet communications to many destinations. IP multicasting is the transmission of IP datagrams to a “host group”, ie, a set of one or more hosts identified by a single IP destination address. A multicast datagram is supplied to all members of its destination host group with the same “best effort” type of reliability as a regular unicast IP datagram. That is, it is not guaranteed that a datagram will arrive intact for all members of the destination group or in the same order relative to other datagrams. Host group members are dynamic, i.e., hosts can join and leave at any time. An IP module can receive a datagram only if it has previously sent a request to join the group to the host. There are no restrictions on the location or number of members in a host group. Incoming datagrams addressed to one of these groups are processed exactly as datagrams addressed to one of the individual addresses of the host. Incoming datagrams destined for groups to which the host does not belong are identified by the group address and are discarded without generating an error report or log entry.

  Digital broadcasting, and in particular digital television, allows programs or other communications to be transmitted to many destinations via cable connections or satellite or terrestrial wireless electromagnetic transmission. Broadcast is an IP transmission in that the communication is essentially unidirectional, i.e. if interaction with the destination is desired, the destination response must be over a different link such as the Internet or telephony. It is different in point. Each transmission on a given channel reaches all receivers connected to that channel.

Data streams added to a broadcast service may be transmitted (“encapsulated”) over the same broadcast channel. Thus, a multicast service can be transmitted with a broadcast service in one direction, and this is a convenient way to provide an IP multicast service. One such method is described in the Multimedia Car Platform (MCP) project described at the Internet site http://mcp.fantastic.ch/. Another method is the publication of international patent application publication no. It is described in WO00 / 48361.
It is desirable to save on the use of transmission bandwidth ("spectrum") for multicast services transmitted with digital broadcasts.

[Summary of Invention]
The present invention provides a method and apparatus for providing an Internet Protocol (IP) multicast service over a broadcast channel as set forth in the appended claims.

[Detailed Description of Preferred Embodiments]
FIG. 1 shows an apparatus for transmitting internet protocol datagrams over a digital video broadcast network. The broadcast network includes a transmitter apparatus including an antenna 1, and each antenna 1 covers each broadcast cell 2 defined by its operating range. In this embodiment of the invention, the broadcast system is a digital television broadcast system according to the European Telecommunications Standards Institute (“ETSI”). However, other broadcast standards may be used in other embodiments of the invention. The particular system shown is a terrestrial broadcast system according to standard DVB-T, but the invention is also applicable, for example, for broadcasting from satellites or via cable systems as well. Will be accepted. The system includes a television signal including video and audio content, and a source of related signal information, and transmission from the antenna 1 to the receiver or user terminal device 3 is unidirectional.

  The system is also connected to an Internet infrastructure 4 that can generate “private data” in the form of data carousels or IP datagrams for transmission over a broadcast network. The broadcaster's device includes a network 5 of Internet terminal devices connected to the Internet infrastructure 4. The broadcaster network 5 of the terminal device and the network of the broadcast transmitter device including the antenna 1 include the DVB specification ETSI EN301 192v1.2.1 for data broadcasting and the implementation guidelines ETSI TR101 202 192v. In accordance with 1.1, they are interconnected via a gateway 6 that encapsulates IP traffic into a stream of television MPEG2 signals.

  Depending on the broadcaster's choice, the IP / DVB gateway 6 can encapsulate IP in broadcasts for different sized ranges, including one or more broadcast cells. All user terminal devices 3 within the service-provided range can receive the same IP packet coming from the IP / DVB gateway 6. In order to reach the user via the broadcast link, the IP packet must be routed to the IP / DVB gateway 6 serving the area where the user is located.

  Referring now to FIG. 2, the Internet infrastructure 4 includes devices that provide IP multicast services using an IP multicast protocol according to Internet Protocol version 4. It will be appreciated that other Internet protocol versions could be used in accordance with the present invention. The IP multicast protocol allows IP datagrams to be sent from a source to many destinations using a single multicast address. In order to support multicast, network entities need some light application (repair).

  The infrastructure for performing multicast over the standard Internet typically includes a multicast server 7 and a multicast router 8 that provides multicast communications to clients 9. In operation, the multicast server 7 begins by announcing a multicast session. The announcement may be made using a multicast protocol such as the session announcement protocol (“SAP”) according to the current text of the Internet Engineering Task Force (“IETF”) standard, for example, email, newsgroup, This is done via a web page or directory. A host wishing to be a client for such a session must apply to the local multicast router 8 using the Internet Group Management Protocol ("IGMP"), and version 3 of the Internet Group Management Protocol. Is IETF version 6 and the Internet group management protocol includes two-way communication as shown in FIG. Each multicast router will broadcast a multicast session in all sub-networks served by that multicast router if at least one user subscribes.

  In a multicast communication over a standard Internet structure according to the current text of the IETF standard, a multicast client 9 applying for a session in order to avoid unnecessary exchange of messages as a user applies for a given multicast session. Are sent to the multicast router 8 during the subscription period by the IGMP protocol, and are also broadcast to other users in the sub-network served by the local multicast router 8. Other users served by the same sub-network are prohibited from receiving the first applicant's application message and then sending their own registration message.

  The local multicast router 8 accepts all multicast messages to the specific addresses (222.0.0.1 and 222.0.0.2) reserved for multicast communication. Once the message has been received due to the registration of the multicast client 9 and the time of the multicast session has arrived, the routing protocol and algorithm should allow the multicast datagram to be propagated and at least one multicast Select all sub-networks that the client 9 knows has registered to receive multicast packets.

  The connection between the multicast router 8 and the multicast client 9 over the standard Internet infrastructure includes a point-to-point connection (point-to-point connection) or a connection that supports only unicast services It will be appreciated to obtain. Therefore, it is still necessary to duplicate the packet downstream of the multicast router 8. On the other hand, communication of multicast data over a broadcast link will avoid the requirement for any duplication of packets. Broadcast links can also provide large and guaranteed bandwidth for transmission of multicast services. Moreover, the quality of service (QoS) provided by DVB broadcasting is guaranteed once the service has begun via the broadcast transmission system. Accordingly, it is desirable to be able to provide a multicast service via a broadcast network such as the DVB broadcast network illustrated in FIG.

  In a standard Internet infrastructure, even if only one user subscribes, a multicast service is always guaranteed once the service is announced, but the service is a “best effort” policy. It's not the case from In other words, the packet is sent to the user in the form possible and possible, and sufficient bandwidth availability is not checked, so that the service received by the user may actually be inadequate.

  However, in this embodiment of the invention, the available bandwidth of the DVB broadcast network for multicast services does not allow to broadcast all possible sessions and needs to be selective. is there. In particular, the provision of multicast services over a broadcast transmitter network is subject to the availability of sufficient transmission resources for each multicast session and the number of successfully registered for the multicast session, and the return path is It is provided for the registration of the multicast client 9, which is always via a different link from the broadcast transmission, taking into account that the broadcast transmission is unidirectional. In fact, more multicast sessions can be announced than expected to be transmitted at the final proposed time. The selection of which session to broadcast is made as a function of the resources available in a given DVB range and the number of multicast clients 9 that subscribe to sessions in that range. The broadcaster may choose to cancel or postpone the session that determines that the broadcaster will not broadcast as announced.

  Another feature of this embodiment of the invention is that the protocol allows two or more multicast clients serviced by a given local multicast router 8 to register for a given multicast session; And truly, incentives are given to all users interested in registration in order to obtain as accurate a measure of the demands of each proposed specific multicast session.

  In the embodiment of the invention shown in FIG. 3, the DVB-T transmitter network 10 is supplied with IP and DVB data via a gateway 6, and the gateway 6 serves as a multicast router 8. To do. Each multicast client 9 has an interactive link 11, and the interactive link 11 is secured by a telecommunications link according to the UMTS standard in the preferred embodiment of the present invention. Note that return links to other wireless communication standards or via fixed line communication are also possible. The multicast service is transmitted over the DVB-T network 10 in response to registration performed by the multicast client 9 using the IGMP protocol.

  In an embodiment of the present invention, communication between the multicast client 9 gateway 6 and the multicast router 8 over the return link 11 uses the one-way link routing protocol (“UDLR”) described in IETF RFC3077. It is certainly performed as the “tunnel” 12 used.

  This standard is intended to allow the use of standard Internet protocols over one-way links, such as DVB, so that one-way networks behave similarly to standard Internet two-way networks. Multicast session announcements are broadcast over a one-way broadcast link. The response from the multicast client 9 is then returned to the IP / DVB gateway 6 and the multicast router 8 via the interactive link 11. For this purpose, the gateway IP address is broadcast to all DVB receivers using a one-way broadcast with the dynamic tunnel configuration protocol specified in UDLR.

  In accordance with the current text of the UDLR standard, DVB cannot communicate directly with other nodes in the same subnetwork, so DVB gateway 6 and multicast router 8 will receive registration messages it receives via DVB broadcasts. Will broadcast. However, according to this embodiment of the invention, the IP / DVB gateway 6 and the multicast router 8 block the registration messages it receives and do not broadcast them via DVB broadcasting. Thus, each multicast client 9 increases the chance that the multicast session is actually broadcast so that the multicast session is announced in the broadcast range that the multicast client 9 receives, so that any multicast client 9 is interested in • Have an incentive to register for the session. Thus, it is possible to count the number of responses received for each IP / DVB gateway 6 and multicast router 8, and use this number to broadcast a particular multicast session within that range. Importance and value can be determined and whether there are not enough broadcast resources available to broadcast all of them can be determined between different sessions.

  Prior to broadcasting a given multicast session, in addition to the response of the multicast client 9, the IGMP protocol also executes an “query” message, which causes the user station to be repeatedly queried throughout the session. , And automatically responds whether the session is still being received. This inquiry is also performed by a response via interactive link 11 in this embodiment of the invention.

  In both cases, a request for a multicast session or a response confirming continued connection with the multicast session is sent to a sufficient number of user stations at a given IP / DVB gateway 6 and multicast router 8, ie multicast. It is necessary to receive from the client 9 and continue to broadcast or broadcast its multicast session by its gateway and multicast router.

  If a multicast session broadcast is canceled or postponed, the user is warned by sending a session announcement protocol cancellation message specified in IETF RFC2974. If the user still desires a multicast service, the user may attempt to access the multicast service via a different multicast server.

  The embodiment of the invention shown in FIG. 4 includes a DVB-T network 10 that includes a transmitter 1, which is linked via an Internet infrastructure 4 and a broadcaster IP network 5, It is linked to an IP / DVB gateway 6 that provides an interface between the broadcaster IP network 5 and the DVB-T network 10. The Internet infrastructure 4 includes a multicast server 7 and a multicast router (not shown in FIG. 4).

  The broadcaster IP network 5 also includes a multicast manager device 14 linked to the multicast server 7 and the multicast router and linked to the IP / DVB gateway 6.

  The interactive uplink 13 is provided from the mobile terminal device 9 to the multicast manager 14, preferably via wireless communication in accordance with GPRS, WLAN or UMTS standards.

  The response of the multicast client 9 that registers for the multicast session is sent along with information about the IP / DVB gateway 6 that the multicast manager 14 receives from the IP / DVB gateway 6 using the session announcement protocol. Directed to 14 unique multicast service addresses. The multicast manager 14 controls the multicast session as a function of the number of multicast clients 9 that register for that session for transmission through the respective gateways via a plurality of IP / DVB gateways 6 and for each IP / Transmission of a multicast session at DVB gateway 6 is conditioned on receiving requests for sessions at that gateway from a sufficient number of user stations served by that gateway.

  More specifically, each multicast manager 14 receives an announcement of an upcoming multicast session from the multicast server 7 like any other user in the Internet, using the session announcement protocol, and the announcement. Is stored in the cache in the form of a multicast session directory service. The multicast manager 14 inserts a session description as a session description protocol according to the current text of the IETF standard RFC 2327 into a stream of data broadcast from each IP / DVB gateway 6 controlled by the multicast manager 14. Is received by the mobile terminal device 9 provided by the multicast manager 14. On receipt of a certain number of requests from multicast clients 9 serviced by different IP / DVB gateways 6 that are greater than the threshold number, the multicast manager 14 is responsible for the corresponding multicast session for the corresponding gateway. To apply. The threshold number is a function of the resources available to broadcast the session from the IP / DVB gateway 6 involved, and is set to exclude any other multicast session with fewer subscribers And expands the resources available for a multicast session by using bandwidth.

  Again, the user station is preferably queried repeatedly during the course of the multicast session to check that the subscribed multicast clients are still sufficient, and continued transmission of multicast data is sufficient It is conditional on receiving responses from any number of multicast client stations.

  The response from the multicast client 9 is transmitted via the interactive link 13 which is connected to the Internet infrastructure 4 for forward transmission of the response to the multicast manager 14. These responses are not retransmitted to other multicast clients 9. Thus, the multicast client 9 has an incentive to register for a given multicast session, and the number of registrations received is a reliable measure of the potential demand of a given session.

  FIG. 5 shows a flow chart of the exchange of messages among the multicast server 7, multicast manager 14, gateway 6 and mobile node or multicast client 9. In this example, preparation for the broadcast of the multicast session begins with a session announcement using the session announcement protocol and including a description according to the session description protocol, as indicated by reference numeral 15. Session announcement 15 is made at a generally known multicast address and using a port number that identifies the announcement protocol used (SAP in this example). The session announcement 15 is broadcast during the period it occurs prior to the associated session (“time to live”) and communicated to the IP / DVB gateway 6, which in turn receives the IP / DVB gateway 6. , Send the above session announcements without interrupting them.

  The multicast session directory service tool of the multicast manager 14 allows the multicast manager 14 to maintain a list of all recently announced session descriptions and to send a list of available sessions to each gateway 6 To. Information regarding the identification of each gateway 6 and its associated multicast manager address is included in the broadcast announcement, thereby allowing the user to respond to the multicast manager 14 corresponding to the gateway 6 serving that multicast client 9. This information is then transmitted from the multicast manager 14 to the associated gateway 6 as indicated by reference numeral 16. The multicast manager 14 checks whether the multicast sessions announced by the multicast server are intended for the range covered by the particular gateway 6 and sends only those sessions intended. The selected session announcement 17 is then sent along with the multicast manager information to those multicast clients 9 within the scope of the DVB transmitter network 10 covered by the associated gateway 6 via the DVB transmitter network 10. Broadcast in a merry-go-round method of data. In the preferred embodiment of the present invention, the session announcement 17 is made using the announcement support descriptor described in the DVB service information of ETFI EN300 468V1.4.1. It should be noted that the above information could be transmitted in a DVB stream using another IP via a DVB encapsulation mechanism.

  Each multicast manager 14 receives information regarding the bandwidth available for private data within the broadcast range provided by each of its DVB / IP gateways 6 it controls. That is, at a given IP / DVB gateway 6, the number of such responses that the broadcast of a given multicast session receives from a multicast client 9 served by that particular gateway identified in the response. Control as a function.

  The user at each mobile terminal 9 browses the information received for the different available multicast sessions and identifies the location of the user, ie the gateway 6 that sent the announcement to the user. You can sign up for it by sending a session identification. The response is communicated to the address of the multicast manager indicated in the announcement as in reference numeral 18. In an alternative embodiment, the location information of the mobile terminal is given by the DVB broadcast cell identification (ID), which allows the multicast manager 14 to identify the gateway serving the user.

  If the number of user subscriptions is greater than the threshold for excluding extra multicast sessions for that particular range of DVB transport network 10, then the multicast manager applies for the multicast session as in reference number 19, so that the corresponding IP / DVB gateway 6 is informed. The IP / DVB gateway 6 then subscribes to the multicast session using the IGMP protocol as in reference numeral 20. When the multicast session begins, the multicast data is communicated from the multicast server 7 to the IP / DVB gateway 6 and passed to the DVB transmitter network 10, as in reference numeral 21, where the data is As indicated by reference numeral 22, it is encapsulated as private data and transmitted to the multicast client 9 via the transmitter 1. A multicast client 9 within range of the DVB transmitter network 10 served by the gateway 6 then receives the multicast session at the corresponding multicast address.

  While the multicast session is being broadcast, the DVB / IP gateway 6 continues to send further session announcements generated by the multicast manager 14 over the DVB transport stream at regular intervals, and the session is terminated by the broadcaster. Stop only when it is done or canceled. If the broadcaster cancels a multicast session, the multicast manager 14 stops the corresponding notification and generates a session cancellation notification using the session notification protocol.

  In the preferred embodiment of the present invention, the multicast client 9 performs an implicit timeout for the session. If the session announcement message is not received within a predetermined period from the time of the previous session announcement, the terminal device thinks that the multicast session has been canceled without waiting for receipt of the session cancellation announcement, and immediately multicast It can attempt to receive the service over an alternative multicast link.

FIG. 1 is a schematic diagram of a system for providing Internet services via a broadcast channel. FIG. 2 is a schematic diagram of a system that provides multicast service over the Internet infrastructure. FIG. 3 is a schematic diagram of a system for providing Internet Protocol multicast service over a broadcast channel in accordance with one embodiment of the present invention. FIG. 4 is a schematic diagram of a system for providing Internet Protocol multicast service over a broadcast channel according to another embodiment of the present invention. FIG. 5 is a flow chart of message exchange in the operation of the system of FIG.

Claims (11)

If at least a request (18) is received for multicast data from one user station (9), the multicast data is sent via the digital broadcast channel to the user station (9) through the multicast router (8). An Internet protocol multicast service providing method transmitted together with a digital broadcast signal,
Transmission of the multicast data by the multicast router is conditioned on reception of the request (18) for the multicast data from the multicast router by a plurality of user stations (9) . The transmission of the multicast data (22) by the multicast router is conditional on receiving a greater number of requests (18) from the user station (9) than a threshold number;
The method of claim 1, wherein the threshold number is a function of bandwidth available for multicast transmission over the broadcast channel. The user station (9) is repeatedly inquired,
The method according to claim 1 or 2, wherein continuous transmission of the multicast data (22) by the multicast router is conditioned on reception of responses (18) from a plurality of the user stations (9).   4. Information about the request (18) for the multicast data from the user station (9) is not available to other user stations of the user station (9). The method described in 1. The signals and data are transmitted to the respective broadcast areas via the gateway (6) between the Internet and the broadcast infrastructure (4, 5 and 10),
The transmission of the multicast data (22) within one broadcast range is the gateway of the request (18) for the multicast data from a plurality of the user stations (9) served by the broadcast range. 5. A method according to any one of claims 1 to 4, which is conditional on reception.   The method according to any one of the preceding claims, wherein an announcement (17) of a future multicast data transmission session is transmitted to the user station (9) via the broadcast channel. The request (18) regarding the multicast data from the user station (9) is received by the multicast manager station (14) via a link different from the broadcast channel,
The method according to claim 6, wherein the multicast manager station (14) controls the transmission of the session as a function of the number of requests (18) from the user station.   The method according to claim 6 or 7, wherein a notification of cancellation of a future multicast data transmission session or termination of a current multicast data transmission session is transmitted to the user station (9) via the broadcast channel.   9. The user station (9) according to any one of claims 1 to 8, wherein the user station (9) responds to the multicast data via a communication link different from the broadcast channel using a unidirectional link routing protocol. Method. Transmitter means (1, 10) for transmitting the multicast data (22) to the user station (9) together with the digital broadcast signal via the digital broadcast channel;
Multicast data for selectively supplying the multicast data (22) to the transmitter means (1, 10) in response to receiving the request for the multicast data from a plurality of user stations (9) An apparatus for providing an Internet multicast service by the method according to any one of claims 1 to 9, comprising a supply means. The multicast data supply means comprises:
A multicast server (7) linked to the transmitter means (1, 10) via the Internet infrastructure (4, 5);
A gateway (6) between the Internet (4, 5) and the broadcast infrastructure (10);
The multicast data (22) selectively responding to the number of requests (18) relating to the multicast data (22) received from the user station within the broadcast range served by the gateway (6). 11. The apparatus according to claim 10, further comprising means for enabling transmission of a).

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